Hermaphroditism
By John Avise
()
About this ebook
Eloquently written by an award-winning biologist and pioneer in molecular ecology, this primer traces the phenomenon of hermaphroditism throughout Earth's species and the adaptive significance of alternative sexual systems. The volume's accessible and richly illustrated text covers the evolutionary origins of hermaphroditism and its historical and fictional instances, proving the relevance of dual sexuality to the everyday world. John C. Avise describes the genetics, ecology, phylogeny, and natural history of hermaphroditic plants, fish, and invertebrate animals and details organisms that either reproduce simultaneously as male and female or switch routinely between one sex and the other. Filled with surprising creatures and inherently compelling topics, this book stands alone in its clear yet comprehensive treatment of hermaphroditism and its unique challenge to the supremacy of separate sexes.
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Hermaphroditism - John Avise
HERMAPHRODITISM
HERMAPHRODITISM
A Primer on the Biology, Ecology,
and Evolution of Dual Sexuality
JOHN C. AVISE
WITH ORGANISMAL LINE-DRAWINGS
BY TRUDY NICHOLSON
COLUMBIA
UNIVERSITY PRESS
NEW YORK
Columbia University Press
Publishers Since 1893
New York Chichester, West Sussex
cup.columbia.edu
Copyright © 2011 Columbia University Press
All rights reserved
E-ISBN 978-0-231-52715-6
Library of Congress Cataloging-in-Publication Data
Avise, John C.
Hermaphroditism : a primer on the biology, ecology, and evolution of dual sexuality / John C. Avise.
p. cm.
Includes bibliographical references and index.
ISBN 978-0-231-15386-7 (cloth : alk, paper)—ISBN 978-0-231-52715-6 (ebook)
1. Intersexuality. 2. Intersexuality in animals. I. Title.
QP267.A95 2011
616.6’94—dc22
2010039958
A Columbia University Press E-book.
CUP would be pleased to hear about your reading experience with this e-book at [email protected].
References to Internet Web sites (URLs) were accurate at the time of writing. Neither the author nor Columbia University Press is responsible for URLs that may have expired or changed since the manuscript was prepared.
Cover images: Front, Clark’s anemonefish (Amphiprion clarkii); back, brown garden snail (Cantareus aspersus) and Oregon checkerbloom (Sidalcea oregana). In these and many other hermaphroditic plant and animal species, each dual-sex individual can reproduce both as a male and as a female during its lifetime.
To J.J. and Buddy,
who remind me every day
to retain a sense of self-worth
and find pleasure in simple things
CONTENTS
PREFACE
The Phenomenon of Dual Sexuality
Hermaphroditism in Fiction
Hermaphroditism in the Real World
ONE Two Sexes in One
Maleness and Femaleness
Anisogamy and the Separate-sex Condition
Evolutionary Origins
Evolutionary Ramifications
Sex Ratios in Separate-sex Taxa
Relationship to Sexual Selection and Mating Systems
Impact on Demographic Parameters
Sex Ratios in Hermaphroditic Taxa
Hermaphroditism Versus Separate Sexes
Fitness Considerations
Mating Systems and Related Phenomena
Sex Allocation
Phylogenetic Legacy Versus Contemporary Adaptive Significance
Summary
TWO Dual-sex Plants
Terminology
Alternative Sexual Systems: Natural History and Examples
Hermaphroditism
Monoecy
Andromonoecy
Gynomonoecy
Gynodioecy
Androdioecy
Trioecy
Sex-changers
Dioecy
Cosexuality Versus Dioecy
Ecological Considerations
Phylogenetic Character Mapping
Transitional States
An Evolutionary Enigma
Selfing Versus Outcrossing
Inbreeding
Coadapted Genotypes
Fertilization Insurance
Sex Allocation
Sexual Selection in Plants
Summary
THREE Dual-sex Invertebrates
Biological Examples
Reef-building Corals
Love-dart Snails, Earthworms, and Sea Slugs
Sperm-storing Freshwater Snails
Sex-changing Limpets, Isopods, and Polychaetes
Androdioecious Clam Shrimps and Gynodioecious Sea Anemones
Protandric Simultaneously Hermaphroditic Shrimps
Quasi-asexual Flatworms
Other Oddities
Sex Determination and Pseudohermaphroditism
Evolutionary Histories: Gonochorism and Hermaphroditism
Phylogenetic Character Mapping
Gynodioecy and Androdioecy
Genetics
Selective Pressures
Selfing Versus Outcrossing
Genetic Considerations
Ecological Considerations
Joint Genetic and Ecological Considerations
Sex Allocation in Simultaneous Hermaphrodites
Selfing and Allocation to Female Function
Stress and Allocation to Male Function
Local Mate Competition
Local Resource Competition
Brooding Constraints
Intra-individual Trade-offs
Sexual Conflicts
Other Factors
Sex Allocation in Sequential Hermaphrodites
The Size-advantage Hypothesis
Mating Systems
Conclusions About Sex Allocation Theory
Sexual Selection
Summary
FOUR Dual-sex Vertebrates
Sexual Flexibility
Evolutionary Lability
Ontogenetic Plasticity
Sequential Hermaphroditism
The Cast of Players
Evolutionary History
Adaptive Significance of Alternative Modes
Simultaneous Hermaphroditism
The Cast of Players
Evolutionary Constraints
Mating Behaviors in Outcrossers
Self-fertilization
History of Genetic Research on the Mangrove Rivulus
Adaptive Significance of Selfing
Summary
GLOSSARY
REFERENCES CITED
INDEX
PREFACE
The Phenomenon of Dual Sexuality
Who among us has not fantasized, at one time or another, about becoming a member of the opposite sex? If you are a man, what would it feel like to be a woman, if only for a day, a week, or a year? And if you are a woman, what would it feel like to be a man? For most people, such fantasies are idle because our genes and hormones normally dictate that each of us remains of one sex from conception to death. However, for individuals in several hundred species of fish, as well as for those that comprise numerous species of plants and invertebrate animals, experiencing life both as a male and as a female is the reproductive norm. Such dual-sex organisms are hermaphrodites.
Among the vertebrates (animals with backbones), approximately 99% of all species consist of separate-sex individuals, meaning that each individual is either male or female. Most of the other 1% of vertebrate species are hermaphroditic, ¹ and essentially all of these are fishes. In some hermaphroditic fish species, an individual may begin its life as a functional male and then later switch to become a functional female, whereas in other species most individuals begin life as females before perhaps later transforming into functional males. In a few fish species, particular individuals switch back and forth repeatedly between male and female. And in still other fish species, an individual can be both a functional male and a female at the same time. In some of these simultaneous hermaphrodites, an individual may alternate between male and female behavioral roles during a spawning episode with another hermaphrodite. Finally, in one small taxonomic group of fishes, each hermaphroditic individual normally reproduces by fertilizing itself. When such selfing
—an intensely incestuous behavior—is repeated generation after generation, the result is a highly inbred lineage, the members of which can become so genetically uniform as to be, in effect, clonally identical to one another.
All of these and additional hermaphroditic phenomena in fishes find their near-perfect analogues in many species of plants and invertebrate animals that also display various forms of dual sexuality. For example, approximately 95% of all species of flowering plants (angiosperms) include at least some dual-sex individuals (hermaphrodites), as do more than 50,000 species of invertebrates. In general, the reproductive lifestyles of hermaphroditic organisms can seem outlandish to us humans, who are more accustomed to thinking of the two sexes being housed in separate bodies.
Hermaphroditism in Fiction
Dual sexuality apparently held a special fascination for the ancient Greeks, as gauged by its prominence in their classical mythologies. Indeed, the word hermaphrodite derives from the Greek myth of Hermaphroditus, a son of Hermes and Aphrodite, the ancients’ gods of male and female sexuality. As a boy, Hermaphroditus was raised by nymphs on sacred Mount Ida, in what now is the country of Turkey. At age 15, while swimming naked in a pool near Halicarnassus (modern Bodrum, Turkey), the handsome young man was admired and soon accosted by a lovely naiad—Salmacis—who embraced him, kissed him, and prayed to the gods that they be united forever. Her wish was granted; their bodies blended and Hermaphroditus thereafter was part male and part female, simultaneously. In Greek paintings, Hermaphroditus is often depicted as a winged youth with mixtures of male attributes (including male genitalia) and female attributes (including hairstyle, breasts, and broad thighs).
Tiresias—the blind prophet-priest of Zeus—was another type of hermaphrodite who in this case switched sequentially between male and female. It all began when Tiresias chanced upon a pair of copulating snakes and beat them with a stick. Hera (the wife of Zeus) was infuriated, and punished Tiresias by transforming him into a woman. Tiresias then married, had children, and according to some accounts became a female prostitute of considerable renown. Seven years later, Tiresias again encountered two mating snakes, but this time she left the serpents alone. As a reward, Hera permitted Tiresias to regain the male condition. In an interesting footnote to this story, Tiresias became embroiled one day in an argument between Hera and Zeus about who enjoyed sex more: men (as Hera claimed), or women (as Zeus claimed). Having experienced sex both ways, Tiresias was posed the question, and he answered that the female receives ten times more pleasure. Infuriated by this response, Hera struck Tiresias blind. Zeus could not stop this action, but, in partial compensation, he was able to grant Tiresias the gift of foresight, thereby enabling Tiresias to become a seer.
Agdistis was another hermaphrodite in Greek mythology. (S)he was conceived one day when Zeus fell asleep upon the ground and some of his leaked seed (semen) accidentally impregnated Gaia (mother Earth). Agdistis was a superhuman being, simultaneously male and female. However, the gods feared Agdistis and soon castrated it.
In another story from ancient Greece, hermaphroditism was humanity’s original state. However, Zeus then decided to split the hermaphrodites, only to find that the now-separate genders spent most of their time in futile efforts to reunite. So, Zeus decided to reconstruct the genitalia such that when men and women embraced, they would fit nicely together and thereby conceive and propagate. And so it has been ever since.
Hermaphroditic or androgynous beings are similarly embedded in the religious traditions or mythologies of several other cultures around the world. For example, in one interpretation of Genesis in the Bible, Adam’s body was hermaphroditic originally, but later it was cleaved or partitioned into male and female (Eve) as a part of the fall from grace in the Garden of Eden. In the tribal stories of some native North Americans, a mythological Trickster is mostly male but dresses as a female and gives birth to children. He carries his penis in a box, which he sends to women for purposes of intercourse. In the Dogon peoples of the Mali region in West Africa, a newborn baby who touches male and female outlines—drawn in the sand by a mythical figure—becomes possessed by two souls and may remain androgynous, without a strong proclivity to procreate.
India is especially rich in mythologies entailing dual sexuality. The great Hindu deity Shiva is often portrayed as partially fused with his female alter ego, Parvati. In Buddhism, a male Bodhisattva (a person who has attained Enlightenment) named Avalokitesvara later became a female, Guan Yin. There are East Indian legends in which ancient hermaphrodites are replaced by twins; of individuals who switch month to month between king and queen; of men who were made woman-like by a god’s curse; and of males bearing children. A central feature of Tantrism is the desirability of activating both the male and female components of a person’s inner self, thereby bringing greater wholeness to the life experience. Sequential hermaphroditism can even be intergenerational. For example, a central idea in Hinduism is that souls transmigrate such that an individual is reborn time and again, often in opposite sex to that of the previous life.
Hermaphroditism also recurs as a theme in modern fiction. In Star Wars, Hutts are hermaphrodites, as are Hermats in the series Star Trek: New Frontier. In the novel Raptor by Gary Jennings (1993), the main character is a hermaphrodite, and so too is the protagonist in the book Middlesex by Calliope Stephanides (2002). In the novel The Left Hand of Darkness by Ursula Le Guin (1966), a planet is populated by sequential androgynes. For 24 days each month, these people are sexually inactive, but for the ensuing two days they become either male or female as determined by appropriate negotiation with an interested sex partner.
Hermaphroditism in the Real World
As intriguing as such mythological dual-sex characters may be, they hardly outmatch the marvelous hermaphroditic plants and animals that actually do populate our planet, and that are the subject of this book.
In this book I provide an introductory overview of real-life hermaphroditic organisms. I pay special attention to ecological and evolutionary explanations for the remarkable reproductive behaviors and lifestyles of these dual-sex creatures, which in some respects seem to have achieved a bestof-two-worlds outcome by combining male and female functions within each individual. The book will convey two central themes: hermaphroditic species can be highly successful ecologically and evolutionarily; and their successes (and failures) offer fresh perspectives on the adaptive significance of alternative sexual systems.
Beyond conveying these basic biological messages, this book is meant to be entertaining as well as educational for a wide audience. It is intended for college students, teachers, natural historians, and others who would appreciate a nontechnical introduction to the biology of dual-sex organisms. Hermaphroditism has been addressed in many previous works, but typically either from a mostly theoretical perspective (e.g., Charnov 1982) or as a small and specialized component of much broader topics such as sexual allocation, sperm competition, or sexual selection (Birkhead and Møller 1998). To my knowledge, no other book occupies the current niche: a biologyrich overview of the natural history, ecology, and evolution of the phenomenon of dual sexuality.
Chapter 1 sets the general biological stage by asking what defines maleness versus femaleness in diverse organisms. It contrasts hermaphroditism with the standard separate-sex condition (termed gonochorism in animals and dioecy in plants), and outlines the many ecological and evolutionary topics for which the issue of hermaphroditism is highly germane. The remainder of the book canvases the vast scope of hermaphroditism in the biological world, beginning with plants (chapter 2) and invertebrate animals (chapter 3), and then building on these observations and concepts to describe various hermaphroditic phenomena in fishes (chapter 4). All of the chapters contribute to the broader thesis that hermaphroditism is not only fascinating in its own right but also provides a unique biological vantage for reexamining the ecological and evolutionary significance of familiar separatesex reproduction.
Trudy Nicholson provided the line drawings of animals and plants that grace this book (figs. 2.4–2.9, 3.1, 3.2, 3.4–3.9, 3.12, 3.14–3.16, 4.2–4.9, 4.16–4.22, and the frontispiece). She has illustrated several of my books on natural history, and it is always a joy for me to work with this gifted and conscientious artist. Judith Mank kindly provided unpublished information, from her earlier dissertation research, on the taxonomic distribution of hermaphroditism in fishes. Thanks also go to Joan Avise for several forms of assistance, and to Felipe Barreto, Rosemary Byrne, Diane Campbell, Jinxian Liu, Ann Sakai, Andrei Tatarenkov, Steve Weller, and several anonymous reviewers for helpful comments on various drafts of the manuscript.
¹A few species among the other 1%
consist solely of females who reproduce asexually, or clonally (i.e., by parthenogenesis or related reproductive modes). These all-female species are the subject of a companion book to which interested readers are referred: Clonality: The Genetics, Ecology, and Evolution of Sexual Abstinence in Vertebrate Animals (Avise 2008).
CHAPTER ONE
Two Sexes in One
A hermaphrodite is an individual that produces functional male gametes and female gametes (sex cells) during its lifetime. This capacity to reproduce both as male and female has many biological ramifications. It raises, for example, the issue of what defines a male versus a female in any species, which in turn motivates the question of what constitutes a male gamete versus a female gamete. With respect to ontogeny (individual development), hermaphroditism begs questions about the genetic and environmental determinants as well as the proximate hormonal and physiological underpinnings of dual sexuality. With respect to ethology (behavior), hermaphroditism raises questions about sexual roles, such as what reproductive tactics an individual might employ to enhance its genetic fitness by investing in reproduction as a male versus as a female at various times during its life. With respect to genetics, hermaphroditism raises questions about the consequences of self-fertilization versus outcrossing for each dual-sex specimen’s fitness, and for the broader genetic architectures of populations of dual-sex individuals. With respect to natural history, hermaphroditism raises many questions about how natural selection views different modes of reproduction by dual-sex organisms. With respect to ecology, hermaphroditism touches on topics related to many sexual phenomena, such as population sex ratios and the operation of sexual selection (a form of selection arising from differences in mating success among conspecific individuals). Finally, with regard to evolutionary history, hermaphroditism raises questions about the phylogenetic origins and transformations among alternative reproductive modes, and about the selective forces that sometimes appear to have favored a long-term retention of the dual-sex lifestyle. This book addresses all of these and related topics.
All forms of hermaphroditism entail the joint production by an individual of male and female gametes. Depending on the species or situation, the gametes that unite to form each zygote (fertilized egg) might come from the same hermaphroditic individual (via self-fertilization) or from separate individuals (via outcrossing). In either case, hermaphroditic species are sexual reproducers, as opposed to asexual or clonal reproducers. Thus, they join the vast majority (99.9%) of multicellular animal and plant species that engage routinely in sex, i.e., in cellular processes that entail the regular production (during gametogenesis) and union (during fertilization or syngamy) of male and female gametes (Williams 1975). From an evolutionary-genetic perspective, sex in multicellular organisms is basically synonymous with the temporal intercalation of meiosis that produces haploid gametes, and syngamy that restores the diploid condition (fig. 1.1). Sexual reproduction greatly facilitates genetic recombination, and clearly has been an extremely successful evolutionary strategy.
FIGURE 1.1 Simplified diagram of meiosis (during gametogenesis) and syngamy (fertilization), which characterize sexual reproduction. In separate-sex animal species, oogenesis (the production of oocytes or unfertilized eggs) and spermatogenesis (the production of sperm) take place in separate female and male individuals. In dual-sex species, each hermaphroditic individual normally has the capacity to produce both male and female gametes, either simultaneously or sequentially.
Among the vertebrates, true functional hermaphroditism is essentially confined to several hundred species of fishes. However, in both the scientific and popular literature, the word hermaphrodite sometimes is encountered in reference to particular human individuals or to occasional atypical specimens in other vertebrate taxa such as fish or frogs. Such cases usually refer to a sexual ambiguity that arises because an individual’s genitalia or other sexual features show intermediate conditions (or various combinations) of what normally we deem to distinguish male from female. For example, in some people the phallus is midway in size and shape between a penis and a clitoris; and in other people the labia are partially fused into a scrotum-like structure. Individuals with such intermediate conditions are best termed intersexual people, rather than hermaphrodites (box 1.1). Intersexualities of this general type also occur sporadically in many separate-sex vertebrate species (Armstrong and Marshall 1964). In this book, however, I will restrict the term hermaphrodite to plant and animal species in which many or most dual-sex individuals produce functional male and female gametes at one time or another during their lifetimes, and thus in which operational hermaphroditism is a standard mode of reproduction.
Maleness and Femaleness
In humans and other mammals, males typically are XY and females are XX with respect to the sex chromosomes. Thus, males are the heterogametic sex (with two different types of sex chromosomes) whereas females are the homogametic sex (with two copies of one type of sex chromosome). Following gametogenesis in diploid females, each haploid oocyte or egg carries one copy of the X-chromosome; and following gametogenesis in diploid males, each haploid sperm carries either an X-chromosome or a Y-chromosome with about equal likelihood (given the segregation rule of Mendelian inheritance). Thus, whether a boy or a girl results from a particular conception is dictated by whether a Y-bearing sperm or an X-bearing sperm fertilizes the focal egg. Remarkably, many dioecious (separate-sex) plant species have chromosomal modes of sex determination that are strikingly similar
to the familiar XY systems of mammals and some other animals (Charlesworth 2002).
However, the XY and XX conditions cannot provide universal definitions or proxies for maleness and femaleness because non-mammalian species have a diversity of other sex-determination mechanisms (Bull 1983). For example, females are the heterogametic sex and males are the homogametic sex in birds and butterflies. (By convention, females in such taxonomic groups are denoted